A control apparatus which controls a virtual camera according to a user operation related to an operation of the virtual camera, when the control apparatus accepts the user operation, determines whether or not to restrict moving of the virtual camera according to the accepted user operation depending on whether or not a predetermined condition for the virtual camera is fulfilled.

A control apparatus which controls a virtual camera according to a user operation related to an operation of the virtual camera, when the control apparatus accepts the user operation, determines whether or not to restrict moving of the virtual camera according to the accepted user operation depending on whether or not a predetermined condition for the virtual camera is fulfilled.

A method, an apparatus, a medium, a terminal, and a device for processing multi-angle free-perspective data are disclosed. The method includes: acquiring a data header file; determining a defined format of a data file according to a parsing result of the data header file; reading and obtaining a data combination from the data file based on the defined format, where the data combination includes pixel data and depth data of multiple synchronized images, and the multiple synchronized images have different perspectives with respect a to-be-viewed area, and pixel data and depth data of each image of the multiple synchronized images has an association relationship; and performing image or video reconstruction of a virtual viewpoint according to the read data combination, where the virtual viewpoint is selected from a multi-angle free-perspective range, and the multi-angle free-perspective range is a range supporting virtual viewpoint switching viewing of the to-be-viewed area.

A method, an apparatus, a medium, a terminal, and a device for processing multi-angle free-perspective data are disclosed. The method includes: acquiring a data header file; determining a defined format of a data file according to a parsing result of the data header file; reading and obtaining a data combination from the data file based on the defined format, where the data combination includes pixel data and depth data of multiple synchronized images, and the multiple synchronized images have different perspectives with respect a to-be-viewed area, and pixel data and depth data of each image of the multiple synchronized images has an association relationship; and performing image or video reconstruction of a virtual viewpoint according to the read data combination, where the virtual viewpoint is selected from a multi-angle free-perspective range, and the multi-angle free-perspective range is a range supporting virtual viewpoint switching viewing of the to-be-viewed area.

A vehicle, a vehicle positioning system and a vehicle positioning method are provided. The vehicle positioning system includes a 2D image sensor, a 3D sensor and a processor. The 2D image sensor is configured for obtaining 2D image data. The 3D sensor is configured for obtaining 3D point cloud data. The processor is coupled to the 2D image sensor and the 3D sensor, and configured for merging the 2D image data and the 3D point cloud data to generate 3D image data, identifying at least one static object from the 2D image data, obtaining 3D point cloud data of the static object from the 3D image data based on each one of the at least one static object, and calculating a vehicle relative coordinate of the vehicle based on the 3D point cloud data of the static object.

A vehicle, a vehicle positioning system and a vehicle positioning method are provided. The vehicle positioning system includes a 2D image sensor, a 3D sensor and a processor. The 2D image sensor is configured for obtaining 2D image data. The 3D sensor is configured for obtaining 3D point cloud data. The processor is coupled to the 2D image sensor and the 3D sensor, and configured for merging the 2D image data and the 3D point cloud data to generate 3D image data, identifying at least one static object from the 2D image data, obtaining 3D point cloud data of the static object from the 3D image data based on each one of the at least one static object, and calculating a vehicle relative coordinate of the vehicle based on the 3D point cloud data of the static object.

Systems and methods for displaying a three-dimensional (3D) workspace, including a 3D internet browser, in addition to a traditional two-dimensional (2D) workspace and for browsing the internet in a 3D/virtual reality workspace and transforming and/or upconverting objects and/or visual media from the 2D workspace and/or 2D webpages to the 3D workspace as 3D objects and/or stereoscopic output for display in the 3D workspace.

Systems and methods for displaying a three-dimensional (3D) workspace, including a 3D internet browser, in addition to a traditional two-dimensional (2D) workspace and for browsing the internet in a 3D/virtual reality workspace and transforming and/or upconverting objects and/or visual media from the 2D workspace and/or 2D webpages to the 3D workspace as 3D objects and/or stereoscopic output for display in the 3D workspace.

A method for seamless transition from a 2D surround view to a 3D surround view. The method includes initializing the 2D-SRV processing chain, displaying the 2D surround view while waiting for HLOS handshake to complete and upon completion of a HLOS handshake, initializing a 3D-SRV processing chain and waiting for a 3D-SRV buffer output; disabling the 2D-SRV display pipeline and enabling a 3D-SRV display pipeline; enabling switchback monitor; atomically switching to 3D surround view seamlessly and glitch free; and displaying 3D surround view on a monitor. Another method includes detecting a crash in a HLOS and seamlessly switching to a 2D surround view from a 3D surround view.

A method for seamless transition from a 2D surround view to a 3D surround view. The method includes initializing the 2D-SRV processing chain, displaying the 2D surround view while waiting for HLOS handshake to complete and upon completion of a HLOS handshake, initializing a 3D-SRV processing chain and waiting for a 3D-SRV buffer output; disabling the 2D-SRV display pipeline and enabling a 3D-SRV display pipeline; enabling switchback monitor; atomically switching to 3D surround view seamlessly and glitch free; and displaying 3D surround view on a monitor. Another method includes detecting a crash in a HLOS and seamlessly switching to a 2D surround view from a 3D surround view.